Soil is the natural reservoir of entomopathogenic fungi that protects them from abiotic factors (Zimmermann, 1986). Hence, most entomopathogenic fungi are isolated from soil by using either selective media [46, 47] or bait trapping method [26, 27]. To our knowledge, except Imoulan et al [6, 7] study, entomopathogenic strains against Medfly have never been isolated from soils naturally containing the populations of this insect or from infected individuals. The introduction of non-native entomopathogenic strains can reduce the effectiveness of these biocontrol agents and may pose ecological risks [8, 10]. Thus, by using medfly pupae as bait in its natural environment soils increase the probability to isolate highly virulent indigenous strains that can adapt to the area environmental conditions [7, 10, 12]. In addition, this technique can also determine the diversity of medfly-associated fungi in the studied area.
EPF strains were isolated on PDA medium after trapping with medfly pupae bait. To our knowledge, this is the first report of using C. capitata pupae as bait to trap entomopathogenic fungi. During the trapping test, 300 bait pupae (23%) out of 1320 pupae were infected with fungi. Moreover, all of the studied soil samples contained medfly-associated fungi and pupae infection percentages ranged from 3.33% to over 48% in some samples. Similar results have been reported by Imoulan et al [6] in the Moroccan’s Argania spinosa forests and by Keller et al [48] in Switzerland, where respectively 91% and 96% soil samples contained entomopathogenic fungi. However, these rates are very high compared to other studies such as, 71.7% soil samples in Spain [19, 49], 55.5% in China [20], 43% in southern Italy [50], 33.6% in Palestine [51], 20.59% in Turkey [12] and 17.5% in UK [27] contained entomopathogenic fungi. These comparisons must be made cautiously due to the differences in bait species, number of individuals and number of soil samples.
Identification of isolated medfly-associated fungi revealed that the most common strains belonged to genus Fusarium (32%) with 83 isolates followed by Beauveria (19.23%) with 50 isolates, Penicillium, Cladosporium and Scedosporium with frequencies over 8%. High occurrence rates of these genera have been reported in soils of Italy, Palestine and China (Tarasco et al., 1997, Ali-Shtayeh et al., 2003, Sun et al., 2008). Species of these genera, particularly of genus Fusarium and Beauveria exhibit a wide variety of life strategies including associations with insects and plants [32, 52]. On the other hand, our results showed that strains of Acremonium sp., Aschersonia sp., Epicoccum sp. and Aspergillus sp. were less abundant in argan and citrus soils with frequencies less than 6%. Several studies have reported most of these species as entomopathogens [51, 53-55]; while others are classified as opportunistic pathogens [20, 32]. The virulence of these species against medfly was proved during pathogenicity tests. The present study demonstrates that entomopathogenic fungi are common inhabitants in the soils of Souss region. Hence, results of this study confirm the findings of Imoulan, et al. [6] in Moroccan argan endemic forest; nevertheless, diversity of the species observed during this study (10 fungal genera) was greater than obtained by Imoulan (2 genera: Beauveria and Paecilomyces). This difference can be explained by the fact that Imoulan, et al. [6] used Galleria mellonella larvae as bait and selective media for isolation whereas we used a general medium (PDA) and C. capitata pupae as bait.
Principal component analysis (PCA) demonstrated that soil factors are directly correlated to the fungal abundance and infection of pupae. In general, PCA showed that generic richness and ecological balance of soils enhance the chances of insect’s fungal infection. Moreover, high sand content and low silt and clay content in the soil favour fungal abundance and infection process. The effect of soil texture on the abundance and availability of entomopathogenic fungi has been reported by several authors. Quesada-Moraga, et al. [19] demonstrated that soil texture particularly clay content directly influences the abundance and viability of B. Bassiana conidia. They also suggested that high soil clay content improves the abundance and persistence of many entomopathogenic fungi as conidia are adsorbed onto clay particles. Furthermore, Garrido-Jurado, et al. [18] proved that the movement of B. bassiana and M. anisopliae conidia are directly influenced by the soil texture and, adequate sand content promotes the mobility as well as infection percentages of the medfly pupae. On the contrary, excessive sand reduces fungal inoculum due to water drainage. In addition, our results showed that the abundance of entomopathogenic fungi in soil requires a high organic matter content and moderate pH (around 8). Similar results have been reported by previous studies which revealed that entomopathogenic fungi are more abundant in soils with high organic matter content and pH around 8 [14, 19, 48]. This can be explained by the fact that soils with high organic matter content have an ecological balance with low C/N ratio and a large diversity of arthropod and hosts on which entomopathogenic fungi can grow [10]. However, Meyling and Eilenberg [56] showed that high organic matter content influences antagonistic effect and biological activity in soil, which negatively affects entomopathogenic species of Beauveria and Metarhizium. It has also been shown that pH can influence the toxin production of entomopathogenic fungi [19, 57]. The response of fungi to these parameters varies among species. Our results also demonstrated that high level of relative humidity negatively effects the abundance of entomopathogenic fungi and rate of pupae infection. This can be explained by the leaching of inoculum and fast development of saprophytic genera. It is known that the leaching of inoculum is correlated with the amount of water and soil texture [58]. In addition, high relative humidity improves the development of saprophytic fungi and competition over space and nutrients [56].
PCA analysis showed that the soils of argan fields and forests are more suitable for the development of medfly-associated fungi compared to citrus orchards soils. Similarly, Tarasco, et al. [50] reported that entomopathogenic fungi are more abundant in uncultivated and forest soils. In general, citrus and agricultural soils may contain pesticides, which causes high C/N ratio and can prevent the growth of microorganisms. In addition to silty texture, citrus soils have high pH and ionic charge as well as a high relative humidity due to irrigation, which affects the development of entomopathogenic fungi [18, 19]. This environment may also improve the invasion of soil by saprophytic microorganisms that increases the competition for nutrients and space. Contrarily, soils of argan fields and forests do not generally contain chemical residues and are more suitable for microbial growth by maintaining ecological balance between these organisms. Moderate pH, good organic matter content, adequate humidity, silty-sandy texture and absence of toxic pesticides in these soils constitute a good habitat for medfly-associated entomopathogenic fungi. Entomopathogenic fungi also act as endophytes in the absence of host that explains their high abundance in the soils of argan fields having vegetation throughout the year [11, 59, 60]. On the other hand, recently Uzman, et al. [21] have reported that entomopathogenic fungi can even persist in intensively managed vineyard systems. They reported that application of chemicals had no significant effect on the presence of entomopathogenic fungi in vineyard soils of Germany. Hence, this resistance of entomopathogenic fungi to fungicides can be exploited for the biological control of pests even in intensively managed agricultural systems.
Understanding the ecology of entomopathogenic fungi and assessment of their insecticidal efficiency under controlled conditions are necessary before their large-scale applications as biological control agents. Furthermore, the use of indigenous strains seems to be environmentally and ecologically safe strategy.
During the present study, about 10 genera and 22 different species of medfly-associated entomopathogenic fungi were isolated from different types of soil samples from Souss region of Morocco. Results confirmed the presence of entomopathogenic fungi in all soil samples. The genera of Fusarium (32%) and Beauveria (19.2%) were the most abundant. The abundance of these strains was directly affected by the physical and chemical properties of soil such as texture, pH, C/N and organic matter content as well as soil origin. These indigenous strains are a promising option to effectively control C. capitata using bio-control agents. In addition, these results can be useful to determine the suitable soils for applying entomopathogenic fungi against medfly and for the selection of the best adapted fungal species in a particular soil. However, further explorations are needed to select efficient and field-resistant strains.